Modeling of the Effects of Metal Complexation on the Morphology and Rheology of Xanthan Gum Polysaccharide Solutions

Santo, Kolattukudy P.; Fabijanic, Kristina Ivana; Cheng, Chi‐Yuan; Potanin, Andrei

doi:10.1021/acs.macromol.1c01328

Cited by 9 publications

(4 citation statements)

References 77 publications

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“…This was verified by simulations for the xanthan solution with divalent Zn 2+ (Santo, Fabijanic, Cheng, Potanin, & Neimark, 2021). The formation of complex structures inhibited the transition of xanthan chains from random coils to a helical structure and thus the interactions with KGM chains.…”

Section: Micro-dsc Analysismentioning

confidence: 58%

Evolutions of synergistic binding between konjac glucomannan and xanthan with high pyruvate group content induced by monovalent and divalent cation concentration

Qiao,

Luo,

et al. 2024

Food Chemistry

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Section: Micro-dsc Analysismentioning

confidence: 58%

Evolutions of synergistic binding between konjac glucomannan and xanthan with high pyruvate group content induced by monovalent and divalent cation concentration

Qiao,

Luo,

et al. 2024

Food Chemistry

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“…To elucidate the molecular mechanism of the electrostatic-driven coassembly of RPs and CMC, we performed mesoscopic simulations using the dissipative particle dynamics (DPD) method. − In these generic coarse-grained models as illustrated in Figure d, each amino acid in RPs or one glucose unit in CMC is coarse-grained as a single DPD particle, and five types of DPD particles are thus applied to represent the chain units of RPs and CMCs (see the Supporting Information for full details). In the simulations, the initial state was built as a dilute aqueous solution of 80 rice glutelin (the most representative subunit of RPs) in the presence of a preassembled CMC fibril frozen at the center of a rectangular simulation box.…”

Section: Resultsmentioning

confidence: 99%

Biomolecular 1D Necklace-like Nanostructures Tailoring 2D Janus Interfaces for Controllable 3D Enteric Biomaterials

et al. 2023

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Construction of well-ordered two-dimensional (2D) and three-dimensional (3D) assemblies using one-dimensional (1D) units is a hallmark of many biointerfaces such as skin. Mimicking the art of difunctional properties of biointerfaces, which skin exhibits as defense and shelter materials, has inspired the development of smart and responsive biomimetic interfaces. However, programming the long-range ordering of 1D base materials toward vigorous control over 2D and 3D hierarchical structures and material properties remains a daunting challenge. In this study, we put forward construction of 3D enteric biomaterials with a two-strata 2D Janus interface assembled from self-adaptation of 1D protein–polysaccharide nanostructures at an oil–water interface. The biomaterials feature a protein dermis accommodating oil droplets as a reservoir for bioactive compounds and a polysaccharide epidermis protecting them from gastric degradation. Furthermore, the epidermis can be fine-tuned with different thicknesses rendering enteric delivery of a bioactive cargo (coumarin-6) with controllable retention in the intestinal tract from 6 to 24 h. The results highlight a skin-inspired construction of enteric biomaterials by self-adaptation of 1D nanostructures at the oil–water interface toward 2D Janus biointerfaces and 3D microdevices, which can be tailored for intestinal treatments with intentional therapeutic efficacies.

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“…Addition of a salt into a polymer solution can also induce various cross-linking due to metal coordination, which gives rise to changes in membrane morphology, cluster formation, and rheological properties. Neimark et al − used DPD simulations of polymer solutions to gain mechanistic insight into the morphological and rheological changes due to metal coordination in the presence of multivalent cations. The coordinating metal was modeled as a 3D complex of planar, tetrahedral, or octahedral geometry, in which the metal cation was surrounded by either four or six dummy beads that correspond to coordination sites.…”

Section: Proton Exchange Membranesmentioning

confidence: 99%

Coarse-Grained Modeling of Ion-Containing Polymers

2022

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Ion-containing polymers have continued to be an important research focus for several decades due to their use as an electrolyte in energy storage and conversion devices. Elucidation of connections between the mesoscopic structure and multiscale dynamics of the ions and solvent remains incompletely understood. Coarse-grained modeling provides an efficient approach for exploring the structural and dynamical properties of these soft materials. The unique physicochemical properties of such polymers are of broad interest. In this review, we summarize the current development and understanding of the structure–property relationship of ion-containing polymers and provide insights into the design of such materials determined from coarse-grained modeling and simulations accompanying significant advances in experimental strategies. We specifically concentrate on three types of ion-containing polymers: proton exchange membranes (PEMs), anion exchange membranes (AEMs), and polymerized ionic liquids (polyILs). We posit that insight into the similarities and differences in these materials will lead to guidance in the rational design of high-performance novel materials with improved properties for various power source technologies.

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Modeling of the Effects of Metal Complexation on the Morphology and Rheology of Xanthan Gum Polysaccharide Solutions

Cited by 9 publications

References 77 publications

Evolutions of synergistic binding between konjac glucomannan and xanthan with high pyruvate group content induced by monovalent and divalent cation concentration

Evolutions of synergistic binding between konjac glucomannan and xanthan with high pyruvate group content induced by monovalent and divalent cation concentration

Biomolecular 1D Necklace-like Nanostructures Tailoring 2D Janus Interfaces for Controllable 3D Enteric Biomaterials

Coarse-Grained Modeling of Ion-Containing Polymers

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